[1] Yang Weifan, Cao Xiaotao, Zhang Bin, et al. Six degree of freedom precision control for space camera secondary mirror adjusting mechanism[J]. Infrared and Laser Engineering, 2018, 47(7): 0718007. (in Chinese)
Yang Weifan, Cao Xiaotao, Zhang Bin, et al. Six degree of freedom precision control for space camera secondary mirror adjusting mechanism[J]. Infrared and Laser Engineering, 2018, 47(7): 0718007. (in Chinese)
[2] Neill D R, Sebag J, Gressler W. Baseline design of the LSST hexapods and rotator[C]//SPIE Astronomical Telescopes + Instrumentation, 2014, 9151: 91512B.
Neill D R, Sebag J, Gressler W. Baseline design of the LSST hexapods and rotator[C]//SPIE Astronomical Telescopes + Instrumentation, 2014, 9151: 91512B.
[3] Yao Rui, Li Qingwei, Sun Jinghai, et al. Accuracy analysis on Focus cabin of fast[J]. Journal of Mechanical Engineering, 2017, 53(17): 36-42. (in Chinese)
Yao Rui, Li Qingwei, Sun Jinghai, et al. Accuracy analysis on Focus cabin of fast[J]. Journal of Mechanical Engineering, 2017, 53(17): 36-42. (in Chinese)
[4] Han Chunyang, Xu Zhenbang, Wu Qingwen, et al. Optimization design and error distribution for secondary mirror adjusting mechanism of large optical payload[J]. Optics and Precision Engineering, 2016, 24(5): 1093-1103. (in Chinese)
Han Chunyang, Xu Zhenbang, Wu Qingwen, et al. Optimization design and error distribution for secondary mirror adjusting mechanism of large optical payload[J]. Optics and Precision Engineering, 2016, 24(5): 1093-1103. (in Chinese)
[5] Huang Zhen. Space Institutional Research[M]. Beijing: Mechanical Industry Press, 1991. (in Chinese)
Huang Zhen. Space Institutional Research[M]. Beijing: Mechanical Industry Press, 1991. (in Chinese)
[6] Bates D M, Watts D G. Relative curvature measures of nonlinearity[J]. Journal of the Royal Statistical Society, 1980, 42(1): 1-25.
Bates D M, Watts D G. Relative curvature measures of nonlinearity[J]. Journal of the Royal Statistical Society, 1980, 42(1): 1-25.
[7] Wang Jinsong, Wang Zhonghua, Huang Tian, et al. Nonlinearity for a parallel kinematic machine tool and its application to interpolation accuracy analysis[J]. Science in China, 2002, 45(1): 97-105.
Wang Jinsong, Wang Zhonghua, Huang Tian, et al. Nonlinearity for a parallel kinematic machine tool and its application to interpolation accuracy analysis[J]. Science in China, 2002, 45(1): 97-105.
[8] Yang Xiaojun, Li Bing, Zhang Donglai. Linear interpolation step length of Stewart platform-based kinematics machine[J]. Journal of Harbin Institute of Technology, 2009, 43(3): 33-36. (in Chinese)
Yang Xiaojun, Li Bing, Zhang Donglai. Linear interpolation step length of Stewart platform-based kinematics machine[J]. Journal of Harbin Institute of Technology, 2009, 43(3): 33-36. (in Chinese)
[9] Wang Xinzhou. Theory and Application of Parameter Estimation for Nonlinear Models[M]. Wuhan: Wuhan University Press, 2002. (in Chinese)
Wang Xinzhou. Theory and Application of Parameter Estimation for Nonlinear Models[M]. Wuhan: Wuhan University Press, 2002. (in Chinese)
[10] Li Shujun, Zhang Yu, Meng Qiaoling. Stiffness characteristics of a 6-PSS spatial parallel mechanism[J]. China Mechanical Engineering, 2009, 20(21): 2521-2525. (in Chinese)
Li Shujun, Zhang Yu, Meng Qiaoling. Stiffness characteristics of a 6-PSS spatial parallel mechanism[J]. China Mechanical Engineering, 2009, 20(21): 2521-2525. (in Chinese)
[11] Hu Qiqian, Yao Zhenqiu. Design of Astronomical Telescope[M]. Beijing: China Science and Technology Press, 2012. (in Chinese)
Hu Qiqian, Yao Zhenqiu. Design of Astronomical Telescope[M]. Beijing: China Science and Technology Press, 2012. (in Chinese)
[12] Li Dongdong, Zhang Weimin, Sui Haonan, et al. Singularity analysis and non-linear error control of five-axis machining[J]. Computer Integrated Manufacturing Systems, 2019, 5: 1-13. (in Chinese)
Li Dongdong, Zhang Weimin, Sui Haonan, et al. Singularity analysis and non-linear error control of five-axis machining[J]. Computer Integrated Manufacturing Systems, 2019, 5: 1-13. (in Chinese)
[13] Lv Yong, Feng Qibo, Liu Lishuang, et al. Six-degree-of-freedom measurement method based on multiple collimated beams[J]. Infrared and Laser Engineering, 2014, 43(11): 3597-3602. (in Chinese)
Lv Yong, Feng Qibo, Liu Lishuang, et al. Six-degree-of-freedom measurement method based on multiple collimated beams[J]. Infrared and Laser Engineering, 2014, 43(11): 3597-3602. (in Chinese)
[14] Gao Yue, Liu Wei, Lv Shimeng, et al. Six-degree-of-freedom displacement and angle measurement system based on two-dimensional position-sensitive detector[J]. Optics and Precision Engineering, 2018, 26(12): 2930-2939. (in Chinese)
Gao Yue, Liu Wei, Lv Shimeng, et al. Six-degree-of-freedom displacement and angle measurement system based on two-dimensional position-sensitive detector[J]. Optics and Precision Engineering, 2018, 26(12): 2930-2939. (in Chinese)
[15] Liu Lishuang, Lv Yong, Meng Hao, et al. New method for measuring 6-DOF micro-displacement based on multi-collimated beams[J]. Infrared and Laser Engineering, http://kns.cnki.net/kcms/detail/12.1261.tn.20190328.1156.012.html.
Liu Lishuang, Lv Yong, Meng Hao, et al. New method for measuring 6-DOF micro-displacement based on multi-collimated beams[J]. Infrared and Laser Engineering, http://kns.cnki.net/kcms/detail/12.1261.tn.20190328.1156.012.html.